A circularly linked list may be a
natural option to represent arrays
that are naturally circular, e.g. the
corners of a polygon, a pool of
buffers that are used and released in
FIFO order, or a set of processes that
should be time-shared in round-robin
order. In these applications, a
pointer to any node serves as a handle
to the whole list.
An easy to visualize example of how a circular list works might be to imagine a group of people standing in a circle where each person only knows the name of the person to his left. Thus to search for a person in the group, you start with the first person (an arbitrary person in this case) and move to the person he know the name of (i.e. to his left) until you find who you are looking for or come back to the first person again. Adding or removing a person to this group is simply done by placing/taking away a person from the circle and changing the name known by the person to his right (and telling him the name of the person to his left if it is an add). I hope this example makes sense, it is basically the way I used to visualize it when I was learning about linked lists.
Skip Lists support fast (O(log(n))) operations and can be used as a sorted data structure - much like balanced binary search tree. This makes them useful wherever we need fast data insert/remove times (like a linked list but unlike array) and also have fast access times (like an array but unlike in a linked list). They are also good for making fast range queries (e.g. find the sum (or max, min, product, etc.) of all elements in indices [i,j] of the structure).
I cannot think of a sufficiently simple real world metaphor for a skip list, the data structure looks quite more intricate than anything I can expect to see with objects in everyday life. But the wikipedia explanation is quite clear and working through the proof and algorithm for building it should be a good starting point. Here's a link to the original paper which is also quite readable IMO.